Physical attributes: Monitoring the world surrounding the device, including altitude, orientation, temperature, humidity, radiation, air quality, noise and vibration

Functional attributes: Higher-level intelligence rooted in the device’s purpose for describing business process or workload attributes

Actuation services: Ability to remotely trigger, change or stop physical properties or actions on the device.

Examples of IoT in action

There are some pretty well-known IoT products that some of you already use, including:

Nest Thermostat (and others). These allow you to control your AC from your phone, anywhere that you can connect to the Internet.

Smart lights: Same concept, but for lights. You can turn lights on/off from your phone. Phillips Hue is an example of this

Bluetooth Trackers – Tile (https://www.thetileapp.com/) is an example of a Bluetooth Tracker. Put one on that thing you always lose (i.e., car keys). The next time you lose those keys, you can find them again via an app on your phone.

Smart power switches – Belkin’s Wemo Insight Wi-Fi Smart Plug is an example. They let you turn the plug (and therefore anything connected to it) on and off, set schedules for the plug, monitor energy consumption and use, etc. You can also connect it to Amazon Alexa and Google Home for hands-free voice control

Health and exercise trackers – Fitbits “fit” into this category, too.

How does IoT affect libraries?

Here are some ways libraries are already incorporating IoT technology into their libraries:

Smart Building Technology: As libraries retrofit their buildings with newer technology (or build new buildings/branches), they are starting to see more IoT-based technology. For example, some libraries can can adjust heating, cooling and lights from a smartphone app. Some newer building monitoring and security systems can be monitored via mobile apps.

RFID: RFID technology (sensors in books) is a type of IoT technology, and has been around for awhile.

Beacon Technology: There are at least two library-focused companies experimenting with Beacon technology (Capira Technologies and Bluubeam).

People counters: Check out Jason Griffey’s Measure the Future project. Here’s what he says about Measure the Future: “Imagine having a Google-Analytics-style dashboard for your library building: number of visits, what patrons browsed, what parts of the library were busy during which parts of the day, and more. Measure the Future is working to make that happen by using open-hardware based sensors that can collect data about building usage that is now invisible. Making these invisible occurrences explicit will allow librarians to make strategic decisions that create more efficient and effective experiences for their patrons.”

Library classes! Libraries are also teaching classes about the Internet of Things. These include classes focused on introducing patrons to IoT technology, and classes that focus on an aspect of IoT, like a class on making things with Arduinos or how to use your new Fitbit.

The Internet of Things will power the Fourth Industrial Revolution. Here’s how

By 2020 more than 50 billion things, ranging from cranes to coffee machines, will be connected to the internet. That means a lot of data will be created — too much data, in fact, to be manageable or to be kept forever affordably.

One by-product of more devices creating more data is that they are speaking lots of different programming languages. Machines are still using languages from the 1970s and 80s as well as the new languages of today. In short, applications need to have data translated for them — by an IoT babelfish, if you will — before they can make sense of the information.

Then there are analytics and data storage.

security becomes even more important as there is little human interaction in the flow of data from device to datacentre — so called machine-to-machine communication.

Survey: IoT Overtakes Mobile as Security Threat

a report from ISACA, a nonprofit association focused on knowledge and practices for information systems. The 2017 State of Cyber Security Study surveyed IT security leaders around the globe on security issues, the emerging threat landscape, workforce challenges and more.

VR, AR, and the Internet of Things: Life Beyond Second Life

But it gets even more interesting when virtual and augmented reality meet the Internet of Things

when Second Life began, there was a lot of interest, but the toolset was limited — just because of the timeframe, not that the toolset wasn’t a good one for that period. But, things matured. I think it was, in particular, the ability to work in HD that improved things a lot. Then came the ability to bring in datasets — creating dashboards and ways for people to access other data that they could bring into the virtual reality experiment. I think those two things were real forces for change.

A dashboard could pop up, and you could select among several tools, and you could get a feed from somewhere on the Internet — maybe a video or a presentation. And you can use these things as you move through this hyper reality: The datasets you select can be manipulated and be part of the entire experience.

So, the hyper reality experience became deeper, richer with tools and data via the IoT; and with HD it became more real.

We can’t deny the fact that curriculum and the way we teach is becoming unbundled. Some things are going to happen online and in the virtual space, and other things will happen in the classroom. And the expense of education is going to drive how we operate. Virtual reality tools, augmented reality tools, and visualization tools can offer experiences that can be mass-produced and sent out to lots of students, machine to machine, at a lower cost. Virtual field trips and other kinds of virtual learning experiences will become much more commonplace in the next 5 years.

My note: I listened to the report in my car yesterday. It is another sober reminder for being proactive rather then reactive (or punitive). We must work toward digital literacy and go beyond that comfortably numb stage of information literacy.

An Experiment Shows How Quickly The Internet Of Things Can Be Hacked

We have basic security in place in modern devices that screen out the most obvious attacks. Really getting phished, if you will, is more of a problem where you are tricked in surrendering your password or username to a common service. If you plug in your webcam into your router or to your Wi-Fi, you’re relatively safe.

I think the biggest security concern for folks at home would be if their router actually is old, it might have an easily guessed password that someone could gain control. Most modern devices don’t have that problem, but that certainly is a concern for older devices.

Internet of Things: A Primer for Product Managers

The first step to becoming an IoT Product Manager is to understand the 5 layers of the IoT technology stack.

1. Devices

Devices constitute the “things” in the Internet of Things. They act as the interface between the real and digital worlds.

2. Embedded software

Embedded software is the part that turns a device into a “smart device”. This part of the IoT technology stack enables the concept of “software-defined hardware”, meaning that a particular hardware device can serve multiple applications depending on the embedded software it is running.

Embedded Operating System

The complexity of your IoT solution will determine the type of embedded Operating System (OS) you need. Some of the key considerations include whether your application needs a real-time OS, the type of I/O support you need, and whether you need support for the full TCP/IP stack.

Embedded Applications

This is the application(s) that run on top of the embedded OS and provide the functionality that’s specific to your IoT solution.

3. Communications

Communications refers to all the different ways your device will exchange information with the rest of the world. This includes both physical networks and the protocols you will use.

4. Cloud Platform

The cloud platform is the backbone of your IoT solution. If you are familiar with managing SaaS offerings, then you are well aware of everything that is entailed here. Your infrastructure will serve as the platform for these key areas:

Data Collection and Management

Your smart devices will stream information to the cloud. As you define the requirements of your solution, you need to have a good idea of the type and amount of data you’ll be collecting on a daily, monthly, and yearly basis.

Analytics

Analytics are one of they key components of any IoT solution. By analytics, I’m referring to the ability to crunch data, find patterns, perform forecasts, integrate machine learning, etc. It is the ability to find insights from your data and not the data alone that makes your solution valuable.

Cloud APIs

The Internet of Things is all about connecting devices and sharing data. This is usually done by exposing APIs at either the Cloud level or the device level. Cloud APIs allow your customers and partners to either interact with your devices or to exchange data. Remember that opening an API is not a technical decision, it’s a business decision.

5. Applications

This is the part of the stack that is most easily understood by Product teams and Executives. Your end-user applications are the part of the system that your customer will see and interact with. These applications will most likely be Web-based, and depending on your user needs, you might need separate apps for desktop, mobile, and even wearables.

The Bottom Line

As the Internet of Things continues to grow, the world will need an army of IoT-savvy Product Managers. And those Product Managers will need to understand each layer of the stack, and how they all fit together into a complete IoT solution.

Wednesday, October 19, 2016
1:00 p.m. – 2:30 p.m. (Eastern Time)

About the Webinar

As the cost of sensors and the connectivity necessary to support those sensors has decreased, this has given rise to a network of interconnected devices. This network is often described as the Internet of Things and it is providing a variety of information management challenges. For the library and publishing communities, the internet of things presents opportunities and challenges around data gathering, organization and processing of the tremendous amounts of data which the internet of things is generating. How will these data be incorporated into traditional publication, archiving and resource management systems? Additionally, how will the internet of things impact resource management within our community? In what ways will interconnected resources provide a better user experience for patrons and readers? This session will introduce concepts and potential implications of the internet of things on the information management community. It will also explore applications related to managing resources in a library environment that are being developed and implemented.

Education in the Internet of ThingsBryan Alexander, Consultant;

How will the Internet of Things shape education? We can explore this question by assessing current developments, looking for future trends in the first initial projects. In this talk I point to new concepts for classroom and campus spaces, examining attendant rises in data gathering and analysis. We address student life possibilities and curricular and professional niches. We conclude with notes on campus strategy, including privacy, network support, and futures-facing organizations.

What Does The Internet of Things Mean to a Museum?Robert Weisberg, Senior Project Manager, Publications and Editorial Department; Metropolitan Museum of Art;

What does the Internet of Things mean to a museum? Museums have slowly been digitizing their collections for years, and have been replacing index cards with large (and costly, and labor-intensive) CMS’s long before that, but several factors have worked against adopting smart and scalable practices which could unleash data for the benefit of the institution, its collection, and its audiences. Challenges go beyond non-profit budgets in a very for-profit world and into the siloed behaviors learned from academia, practices borne of the uniqueness of museum collections, and the multi-faceted nature of modern museums which include not only curator, but conservators, educators, librarians, publishers, and increasing numbers of digital specialists. What have museums already done, what are they doing, and what are they preparing for, as big data becomes bigger and ever more-networked?The Role of the Research Library in Unpacking The Internet of ThingsLauren di Monte, NCSU Libraries Fellow, Cyma Rubin Fellow, North Carolina State University

The Internet of Things (IoT) is a deceptively simple umbrella term for a range of socio-technical tools and processes that are shaping our social and economic worlds. Indeed, IoT represents a new infrastructural layer that has the power to impact decision-making processes, resources distribution plans, information access, and much more. Understanding what IoT is, how “things” get networked, as well as how IoT devices and tools are constructed and deployed, are important and emerging facets of information literacy. Research libraries are uniquely positioned to help students, researchers, and other information professionals unpack IoT and understand its place within our knowledge infrastructures and digital cultures. By developing and modeling the use of IoT devices for space and program assessment, by teaching patrons how to work with IoT hardware and software, and by developing methods and infrastructures to collect IoT devices and data, we can help our patrons unlock the potential of IoT and harness the power of networked knowledge.

Lauren Di Monte is a Libraries Fellow at NC State. In this role she develops programs that facilitate critical and creative engagements with technologies and develops projects to bring physical and traditional computing into scholarship across the disciplines. Her current research explores the histories and futures of STEM knowledge practices.

I’m not sure if the IoT will hit academic with the wave force of the Web in the 1990s, or become a minor tangent. What do schools have to do with Twittering refrigerators?

Here are a few possible intersections.

Changing up the campus technology space. IT departments will face supporting more technology strata in a more complex ecosystem. Help desks and CIOs alike will have to consider supporting sensors, embedded chips, and new devices. Standards, storage, privacy, and other policy issues will ramify.

Mutating the campus. We’ve already adjusted campus spaces by adding wireless coverage, enabling users and visitors to connect from nearly everywhere. What happens when benches are chipped, skateboards sport sensors, books carry RFID, and all sorts of new, mobile devices dot the quad? One British school offers an early example.

New forms of teaching and learning. Some of these take preexisting forms and amplify them, like tagging animals in the wild or collecting data about urban centers. The IoT lets us gather more information more easily and perform more work upon it. Then we could also see really new ways of learning, like having students explore an environment (built or natural) by using embedded sensors, QR codes, and live datastreams from items and locations. Instructors can build treasure hunts through campuses, nature preserves, museums, or cities. Or even more creative enterprises.

New forms of research. As with #3, but at a higher level. Researchers can gather and process data using networked swarms of devices. Plus academics studying and developing the IoT in computer science and other disciplines.

An environmental transformation. People will increasingly come to campus with experiences of a truly interactive, data-rich world. They will expect a growing proportion of objects to be at least addressable, if not communicative. This population will become students, instructors, and support staff. They will have a different sense of the boundaries between physical and digital than we now have in 2014. Will this transformed community alter a school’s educational mission or operations?

infamous former Bush administration lawyer John Yoo wrote in his 2006 book that Newstead was the “day-to-day manager of the Patriot Act in Congress”.

The Patriot Act was passed in the wake of the 9/11 attacks and brought in a series of new federal crimes related to terrorism. The legislation was broad and much of the government’s expanded surveillance powers stemmed from parts of the act. It enabled, among other things, the controversial Section 215, which was used to justify the National Security Agency’s phone records collection programme.

It also had a “roving wiretap” provision, which allowed government to place a tap on all of an individual’s personal devices based purely on the approval of the notoriously permissive Foreign Intelligence Surveillance Court.

As The Verge points out, the Patriot Act also initiated the practice of “national security letters”, a procedure by which intelligence agencies can informally request data without any kind of court or ex parte authorisation, citing threats to national security. Facebook fields thousands of these requests every year, the content of which is generally subject to gag orders and therefore remains publicly unknown. In her capacity as general counsel, Newstead will be able to approve or deny these requests.

p. 5 a LibGuide was created that provided a better description of the available software for both the Microsoft Hololens and the HTC Vive and also discussed potential applications for the technology.

Both the HTC Vive and the Hololens were made bookable through the library’s LibCalendar booking system, streamlining the booking process and creating a better user experience.

When the decision was made to bring virtual and augmented reality into the McGill University Library, an important aspect of this project was to develop a collection of related software to be used alongside the technology. In building this software collection a priority was placed on acquiring software that could be demonstrated as having educational value, or that could potentially be used in relation to, or in support of, university courses.

For the Microsoft Hololens, all software was acquired through Microsoft’s Online Store. The store has a number of educationally relevant HoloLens apps available for purchase. The app ARchitect, for example, gives a basic sense of how augmented reality could be used for viewing new building designs. The app Robotics BIW allows user to simulate robotic functions. A select number of apps, such as Land of the Dinosaurs and Boulevard, provide applications for natural history and art. There were a select number of apps related to science, mathematics and medicine, and others with artistic applications. All of the HoloLens applications were free but, compared to what is available for virtual reality, the experiences were much smaller in size and scope.

For the HoloLens, a generic user account was created and shared with person who booked the HoloLens at the time of their booking. After logging into this account – which could sometimes prove to be a challenge because typing is done using the headset’s gesture controls – the user could select a floating tile which would reveal a list of available software. An unresolved problem was that users would then need to refer to the HoloLens LibGuide for a detailed description of the software, or else choose software based on name alone, and the names were not always helpful.

For the Microsoft HoloLens, the three most popular software programs were Land of the Dinosaurs, Palmyra and Insight Heart. Insight Heart allow users to view and manipulate a 3D rendering of a high-resolution human heart, Land of the Dinosaurs provided an augment reality experience featuring 3D renderings of dinosaurs, and Palmyra gave an augmented reality tour of the ancient city of Palmyra.

p. 7 Though many students had ideas for research projects that could make use of the technology, there was no available software that would have allowed them to use augmented reality in the way they wanted. There were no students interested in developing their own software to be used with the technology either.

p. 8 we found that the Microsoft HoloLens received significant use from our patrons, we would recommend the purchase of one only for libraries serving researchers and developers.

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Getting Real in the Library: A Case Study at the University of Florida

As an alternative, Microsoft offers a Hololens with enterprise options geared toward multiple users for $5000.

The transition from mobile app development to VR/AR technology also reflected the increased investment in VR/AR by some of the largest technology companies in the world. In the past four years, Facebook purchased the virtual reality company Oculus, Apple released the ARKit for developing augmented reality applications on iOS devices, Google developed Google Cardboard as an affordable VR option, and Sony released Playstation VR to accompany their gaming platform, just to name a few notable examples. This increase of VR/AR development was mirrored by a rise in student interest and faculty research in using and creating new VR/AR content at UF.

To assess the HoloLens’ potential for delivering AR assembly instructions, the cross-platform Unity 3D game engine was used to build a proof of concept application. Features focused upon when building the prototype were: user interfaces, dynamic 3D assembly instructions, and spatially registered content placement. The research showed that while the HoloLens is a promising system, there are still areas that require improvement, such as tracking accuracy, before the device is ready for deployment in a factory assembly setting.

We use Microsoft HoloLens device to augment the user’s experience in the real library and to provide a rich set of affordances for embodied and social interactions.We describe a mixed reality based system, a prototype mixed library, that provides a variety of affordances to support embodied interactions and improve the user experience.

Computer science as an engineering discipline has been spectacularly successful. Yet it is also a philosophical enterprise in the way it represents the world and creates and manipulates models of reality, people, and action. In this book, Paul Dourish addresses the philosophical bases of human-computer interaction. He looks at how what he calls “embodied interaction”—an approach to interacting with software systems that emphasizes skilled, engaged practice rather than disembodied rationality—reflects the phenomenological approaches of Martin Heidegger, Ludwig Wittgenstein, and other twentieth-century philosophers. The phenomenological tradition emphasizes the primacy of natural practice over abstract cognition in everyday activity. Dourish shows how this perspective can shed light on the foundational underpinnings of current research on embodied interaction. He looks in particular at how tangible and social approaches to interaction are related, how they can be used to analyze and understand embodied interaction, and how they could affect the design of future interactive systems.

HoloMuse, an AR application for the HoloLens wearable device, which allows users to actively engage with archaeological artifacts from a museum collection

pick up, rotate, scale, and alter a hologram of an original archeological artifact using in-air gestures. Users can also curate their own exhibit or customize an existing one by selecting artifacts from a virtual gallery and placing them within the physical world so that they are viewable only using the device. We intend to study the impact of HoloMuse on learning and engagement with college-level art history and archeology students.